Modification of the fatty acid composition of Ehrlich ascites tumor cell plasma membranes.

The fatty acyl group composition of Ehrlich ascites tumor cell plasma membranes was modified by feeding the tumor-bearing mice diets rich in either coconut or sunflower oil. When coconut oil was fed, the oleate content of the membrane phospholipids was elevated and the linoleate content reduced. The opposite occurred when sunflower oil was fed. Qualitatively similar changes were observed in the plasma membrane phosphatidylethanolamine, phosphatidylcholine and mixed phosphatidylserine plus phosphatidylinositol fractions. These diets also produced differences in the sphingomyelin fraction, particularly in the palmitic and nervonic acid contents. Unexpectedly, the saturated fatty acid content of the plasma membrane phospholipids was somewhat greater when the highly polyunsaturated sunflower oil was fed. The small quantities of neutral lipids contained in the plasma membrane exhibited changes in acyl group composition similar to those observed in the phospholipids. These fatty acyl group changes were not accompanied by any alteration in the cholesterol or phospholipid contents of the plasma membranes. Therefore, the lipid alterations produced in this experimental model system are confined to the membrane acyl groups.     

Alteration of the fatty acid composition of Ehrlich ascites tumor cell lipids.

The fatty acid composition of Ehrlich ascites tumor lipids was altered markedly $\text{in vivo}$ by changing the type of fat fed to the tumor-bearing mice. As compared with regular chow, large differences were produced in polar and neutral lipid fatty acyl groups when the tumor cells were grown in mice fed coconut oil, sunflower oil or fat deficient diets. Subcellular membrane fractions obtained from these cells exhibited similar variations in fatty acyl composition. This experimental system provides large quantities of malignant cells for study of the relationships between membrane lipid structure and function.     

Sodium-dependent amino acid transport in reconstituted membrane vesicles from Ehrlich ascites cell plasma membranes

Plasma membranes, isolated from Ehrlich ascites tumor cells, were dissolved in 2% cholate, 4 M urea and then reformed into liposomes upon dialysis at 4 degrees with exogenous phospholipids. Reconstituted vesicles regain the ability to transport amino acids. Na+ was shown to accelerate the uptake of alpha-aminoisobutyrate, phenylalanine, and methionine, but not leucine or epsilon-aminohexanoic acid. With the reconstituted vesicles, methionine, but not leucine, inhibited the uptake of alpha-aminoisobutyrate. An apparent Km value for alpha-aminoisobutyrate uptake of 3.0 mM was obtained. This value is close to that observed with the intact cells and the native membrane vesicles. A Na+ gradient (high Na+ outside) increased alpha-aminoisobutyrate uptake, whereas a reversed gradient (high Na+ inside) increased alpha-aminoisobutyrate efflux. The latter flux was increased by valinomycin, suggesting electrogenic transport. A modest extent of coupling between a Na+ gradient and uphill flow of alpha-aminoisobutyrate was observed.     

Relationship between fatty acid and glucose utilization in Ehrlich ascites tumor cells

Glucose greatly increased total free fatty acid (FFA) esterification by Ehrlich ascites tumor cells. However, the FFA concentration of the cells was not altered. Less exogenous FFA was oxidized to CO(2) at any given extracellular FFA:albumin molar ratio when glucose was available, but increasing amounts of radioactive CO(2) were produced as the FFA:albumin molar ratio was raised, even in the presence of glucose. It is suggested that glucose, by providing either energy or an excess of triose acceptor for fatty acid esterification, stimulated FFA uptake only indirectly, by increasing the utilization of FFA subsequent to initial uptake from the medium, i.e., by increasing the turnover rate of the cellular FFA pool. Availability of glucose decreased the oxidation of endogenous lipid radioactivity and the depletion of endogenous lipid ester radioactivity. Most of the radioactivity utilized was derived from phospholipids, and depletion of phospholipid radio-activity was spared when glucose was available. Depletion of cellular total lipid ester also was spared in the presence of glucose. Availability of FFA did not decrease total glucose uptake or its oxidation to CO(2). Glucose utilization by these cells appears not to be regulated by FFA availability in the manner that Randle and coworkers described for muscle.     

Electron-transferring enzymes in the plasma membrane of the Ehrlich ascites tumor cell.

The plasma membrane of the Ehrlich ascites tumor cell contains an NADH dehydrogenase. This activity was shown not to be due to contamination by other subcellular membranes. A variety of electron acceptors have been compared as to rate with the following result: ferricyanide greater than cytochrome c greater than cytochrome b5 greater than glyoxylate greater than dichlorophenolindophenol. Oxygen acceptance could not be detected. The optimum assay temperature and pH ranges were 30--40 degrees C and pH 6--8, respectively. With respect to either NADH or ferricyanide, the kinetics yielded linear double-reciprocal plots. Inhibition of the enzyme by sulfhydryl reagents could be blocked by excess NADH. Detergents such as Triton X-100 or cholate resulted in solubilization of the enzymatic activity, but phospholipase A2 did not. The activity differed from that of the mitochondria in that it was not inhibited by rotenone or antimycin A. The possible involvement of NADH oxidation in the energetics of plasma membrane transport is discussed.     

l-Glutamine transport in native vesicles isolated from Ehrlich ascites tumor cell membranes

Native vesicles isolated from Ehrlich ascites tumor cells accumulate glutamine by means of Na⁺-dependent transport systems; thiocyanate seems to be the more effective anion. The apparent affinity constant for the process was 0.38 mM. The Arrhenius plot gave an apparent activation energy of 12.3 kJ/mol. The structural analogs of glutamine, acivicin (2.5 mM) and azaserine (2.5 mM), inhibited the net uptake by 67 and 70%, respectively. The sulfhydryl reagents mersalyl, PCMBS, NEM, and DTNB also inhibited net uptake, suggesting that sulfhydryl groups may be involved in the activity of the carrier protein. A strong inhibition was detected when the vesicles were incubated in the presence of alanine, cysteine, or serine; in addition, histidine, but not glutamate or leucine, had a negative effect on glutamine transport.     

Characterization of the Ehrlich ascites tumor plasma lipoproteins.

1. The lipoproteins of the Ehrlich ascites tumor plasma were separated into 3 distinct fractions, very low density, low density and high density lipoproteins by preparative ultracentrifugation combined with agarose column chromatography. 2. High density lipoproteins contained 74% of the total protein in the lipoproteins. By contrast, most of the lipids were present in the very low density lipoprotein fraction. 3. The fatty acid compositions of the cholesteryl esters were appreciably different in the very low, low and high density lipoproteins, whereas phospholipid and triacylglycerol fatty acid compositions were quite similar in the 3 lipoprotein fractions. 4. Very low and high density apoprotein electrophoretic patterns on sodium dodecyl sulfate-acrylamide gels were similar to those observed in the corresponding lipoprotein fractions obtained from other mammalian species. The low density fraction, however, contained 7 apoprotein bands, and 32% of the low density apoprotein was soluble in tetramethyl urea. 5. The average molecular weights as determined by analytical ultracentrifugation were 2-10(7) (very low density), 6-10(6) (low density) and 4.4-10(5) (high density).     

Ehrlich ascites tumor cell surface membranes: an abnormality in ether lipid content

Most mammalian neoplasms have a defect in ether lipid content manifested by the presence of abnormally large quantities of 0-alkyl glyceryl ethers, in contrast to normal tissues in which the alk-1-enyl structure predominates. These lipids are for the most part structural. The manner in which tumor cell plasma membranes differ from normal may be important, and it has been hitherto unclear whether or not the 0-alkyl lipid abnormality of neoplasms includes the plasma membrane. The present investigation reveals that 0-alkyl lipids are present in the membranes of Ehrlich ascites tumor cells isolated by several different methods. The amount of 0-alkyl lipid, on a weight basis, represents 1-3 percent of the total phospholipids and 1-4 percent of the total aliphatic lipid. These quantities are the same as or greater than the amount of 0-alkyl lipid found in microsomes, mitochondria, and whole cell homogenate. As is generally the case for intact neoplastic tissues, the quantity of 0-alkyl lipids of Ehrlich ascites tumor plasma membrane is greater than the amount of alk-1-enyl lipids.     

Release of free fatty acids from Ehrlich ascites tumor cells

Ehrlich ascites tumor cells release free fatty acids (FFA) during in vitro incubation in media that contain albumin. The released FFA are derived by lipolysis from endogenous lipid esters. Addition of glucose to the incubation medium greatly decreases the quantity of fatty acid released by the cells. Cyanide, which inhibits endogenous lipid oxidation but not lipolysis, increases the quantity of fatty acid released to media containing albumin and causes free fatty acid to accumulate in the cells in the absence of exogenous albumin. The release of fatty acid, either preformed or derived by lipolysis during prolonged incubations, occurs under conditions of net fatty acid uptake from the incubation medium. Net release of fatty acid from the cell occurs only when fatty acid-extracted albumin is present in the extracellular medium; extrapolation of the data suggests that net release will not occur under physiological conditions. It is postulated that free fatty acid uptake and release are independent processes, the direction of net fatty acid movement being determined by the relationship between cellular free fatty acid concentration (regulating efflux) and the molar ratio of free fatty acid to albumin in the extracellular medium (regulating uptake).     

Molecular size of a Na(+)-dependent amino acid transporter in Ehrlich ascites cell plasma membranes estimated by radiation inactivation

Radiation inactivation was used to estimate the molecular size of a Na(+)-dependent amino acid transport system in Ehrlich ascites cell plasma membrane vesicles. Na(+)-dependent alpha-aminoisobutyric acid uptake was measured after membranes were irradiated at -78.5 degrees C in a cryoprotective medium. Twenty-five percent of the transport activity was lost at low radiation doses (less than 0.5 Mrad), suggesting the presence of a high molecular weight transport complex. The remaining activity (approximately 75% of total) decreased exponentially with increasing radiation dose, and a molecular size of 347 kDa was calculated for the latter carrier system. Vesicle permeability and intravesicular volume were measured to verify that losses in transport activity were due to a direct effect of radiation on the transporter and not through indirect effects on the structural integrity of membrane vesicles. Radiation doses 2-3-fold higher than those required to inactivate amino acid transport were needed to cause significant volume changes (greater than 15%). Vesicle permeability was unchanged by the irradiation. The structural integrity of plasma membrane vesicles was therefore maintained at radiation doses where there was a dramatic decrease in amino acid transport. The relationship between the fragmentation of a 120-130-kDa peptide, a putative component of the Na(+)-dependent amino acid carrier [McCormick, J. I., & Johnstone, R. M. (1988) Proc. Natl. Acad. Sci. U.S.A. 85, 7877-7881], and loss of transport activity in irradiated membranes was also examined. Peptide loss was quantitated by Western blot analysis.(ABSTRACT TRUNCATED AT 250 WORDS)     

Anion transport in the Ehrlich ascites tumor cell: the effect of 2,4,6-trinitrobenzene sulfonic acid

We have investigated the effects of the amino reactive reagent, 2,4,6-trinitrobenzene sulfonic acid (TNBS) on anion transport (chloride and sulfate) and on the K⁺ content of Ehrlich ascites tumor cells. Incubation of tumor cells with TNBS (3 mM or 10 mM) results in a time dependent uptake of this molecule. Tightly bound TNBS caused a loss of K⁺ as well as inhibition of sulfate uptake. Although sulfate transport was inhibited by tightly bound TNBS (40% inhibition with 20 nmoles bound per 10⁷ cells), reversibly bound TNBS exerted much greater inhibition. Kinetic analysis of sulfate transport in the presence and absence of TNBS suggests that: (1) tightly bound TNBS exerts a competitive inhibition by occupying membrane sites remote from the specific transport site, (2) TNBS reversibly interacts with a separate site also in a competitive fashion. Increasing amounts of tightly bound TNBS resulted in an enhanced chloride influx. However, reversibly bound TNBS was without effect. These results are in contrast to the effect of TNBS on sulfate transport and show that TNBS, at least in this cell type, is not a general inhibitor of anion transport.     

Solubilization of alkyldihydroxyacetone-P synthase from Ehrlich ascites cell microsomal membranes.

The enzyme, alkyldihydroxyacetone-P synthase, has been solubilized and partially purified from microsomal preparations of Ehrlich ascites cells after treatment with Triton X-100 and phospholipase C, followed by chromatography on Sepharose 4B. When the Triton X-100 was removed after solubilization the enzyme was still active but eluted in the void volume of the Sepharose 4B column, whereas in the presence of detergent it eluted much later as a single peak of activity, indicating that the solubilized enzyme tends to aggregate unless detergent is present. The lower molecular weight form of alkyldihydroxyacetone-P synthase (in detergent) had an estimated molecular mass of 250,000–300,000 daltons.     

Effects of dietary fat composition on the Ehrlich ascites tumor fluid lipoproteins.

Mice bearing the Ehrlich ascites tumor were fed diets rich in either coconut oil or sunflower oil. From 20 to 40% less lipid was present in the ascites tumor fluid when the mice were fed the sunflower oil diet. This was associated with a reduction in the amount of very low density lipoproteins (VLDL) and high density lipoproteins (HDL), the main lipoprotein fractions present in the ascites tumor fluid. The VLDL from the mice fed sunflower oil contained more cholesteryl esters and a lower free to esterified cholesterol ratio than those from the mice fed coconut oil. Very little change occurred in the composition of the HDL. All of the lipids contained in both lipoprotein fractions exhibited appreciable differences in fatty acid composition. Much more monoenoic and less polyenoic fatty acid were present in the lipids from the mice fed the coconut oil diet, but no appreciable change in saturated fatty acid content occurred. Similar changes in fatty acid composition were observed in the blood plasma of the tumor-bearing mice. There was no qualitative difference in the apolipoprotein patterns of either the ascites fluid VLDL or HDL. Pyrene fluorescence studies indicated that the fluidity of the VLDL was increased when the mice were fed the sunflower oil diets. No difference in HDL fluidity, however, was observed by this technique. These results indicate that the amount, composition, and physical properties of certain of the lipoproteins contained in the ascites tumor fluid can be modified by changing the composition of the dietary fat fed to mice bearing the Ehrlich ascites tumor.